Energy resource endowments - POLES: Difference between revisions

Latest revision as of 16:34, 22 December 2016

Model Documentation - POLES
Model scope and methods - POLES Model concept, solver and details - POLES Temporal dimension - POLES Spatial dimension - POLES Policy - POLES Socio-economic drivers - POLES Population - POLES Economic activity - POLES Macro-economy - POLES Production system and representation of economic sectors - POLES Energy - POLES Energy resource endowments - POLES Fossil energy resources - POLES Uranium and other fissile resources - POLES Bioenergy - POLES Non-biomass renewables - POLES Energy conversion - POLES Electricity - POLES Heat - POLES Gaseous fuels - POLES Liquid fuels - POLES Solid fuels - POLES Grid, pipelines and other infrastructure - POLES Energy end-use - POLES Transport - POLES Residential and commercial sectors - POLES Industrial sector - POLES Other end-use - POLES Energy demand - POLES Technological change in energy - POLES Land-use - POLES Emissions - POLES Carbon dioxide removal (CDR) options - POLES Climate - POLES Non-climate sustainability dimension - POLES Appendices - POLES Data - POLES References - POLES
Corresponding documentation
AIM-Hub BLUES C3IAM COFFEE-TEA DNE21+ GCAM GEM-E3 GRACE IFs IMACLIM IMAGE MESSAGE-GLOBIOM POLES PROMETHEUS REMIND-MAgPIE TIAM-UCL WITCH
Previous versions
Archive of POLES version ADVANCE
Model information
Model link	http://ec.europa.eu/jrc/en/poles https://ec.europa.eu/jrc/en/publication/poles-jrc-model-documentation-0
Institution	JRC - Joint Research Centre - European Commission (EC-JRC), Belgium, http://ec.europa.eu/jrc/en/.
Solution concept	Partial equilibrium (price elastic demand)
Solution method	SimulationRecursive simulation
Anticipation	Myopic

The model distinguishes different geographical representations according to the resource considered.

Supply is linked to demand regions via trade:

Oil: producers all export to single global market "pool"
Gas: large producers export towards 14 importing regions; small producers only supply domestic demand
Coal: large producers export towards 14 importing regions; small producers only supply domestic demand
Solid biomass: producers supply domestic demand or export towards a global market depending on the relative cost of production
Liquid biofuels: similar to solid biomass
Uranium: single global supply cost curve
Primary electricity (hydro, solar, wind): country-specific renewables potentials for power generation for domestic electricity demand

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-== Fossil fuel resources ==
+The model distinguishes different geographical representations according to the resource considered.
-The POLES model differentiates various types of fossil fuels:
+Supply is linked to demand regions via trade:
+* Oil: producers all export to single global market "pool"
-* oil: conventional, tar, heavy and oil shale / onland &amp; shallow, deepwater, artic;
+* Gas: large producers export towards 14 importing regions; small producers only supply domestic demand
-* gas: conventional, shale gas / onland &amp; shallow, deepwater and artic;
+* Coal: large producers export towards 14 importing regions; small producers only supply domestic demand
-* coal: steam and coke.
+* Solid biomass: producers supply domestic demand or export towards a global market depending on the relative cost of production
+* Liquid biofuels: similar to solid biomass
-The description below gives elements for oil, but they can be extended to gas and coal.
+* Uranium: single global supply cost curve
+* Primary electricity (hydro, solar, wind): country-specific renewables potentials for power generation for domestic electricity demand
-[[File:36405505.png|none|600px|thumb|<caption>Static aggregated oil production cost curve</caption>]]
-While this figure gives an aggregated static cost curve, the model actually uses ''dynamic'' cost curve per resource type integrating the cost of energy needs for production for each production country/ region. Consequently POLES fossil fuel cost curves thus evolve over time, by region and with the scenario settings (for instance: a CO2 pricing will affect the production cost of tar sands, ..).
-The supply module transforms resources into reserves through discovery effort (exploration and drilling) that depends on remaining resources, the (dynamic) production cost curve and international fuel prices, through elasticities that capture openness to investment and resource management strategies.
-Reserves are then turn into production depending on remaining reserves, the (dynamic) production cost curve and international fuels prices.
-[[File:36405504.png|none|600px|thumb|<caption>Reserves discovery process in POLES (URR: ultimate Recoverable Resources, DISOIL: Discovery of oil)</caption>]]
-Sources of information include: BGR, USGS, IEA, MIT, industry estimates
-== Biomass resources ==
-Primary biomass resources for energy uses are classified in 3 categories for all POLES 57 countries / regions: energy crops, short rotation crops (cellulosic) and forest residues (cellulosic). Energy crops are dedicated to 1st generation biofuels, the 2 other categories are used in all other energy uses (a further split of biomass feedstocks has been implemented for Europe using information from the model GREEN-X). POLES uses by default a simplified modeling of land use to estimate the potential of these resources: land available, yields, share of harvest/land that can be allocated to energy uses.POLES also uses in a standard way exogenous estimates of potentials: for instance a soft linkage with the model GLOBIOM/G4M has been implemented that goves potential estimates and cost curves for all World regions (with th emodel GREEN-X at EU level). Biomass supply cost curves are attached to the various biomass types and come from GREEN-X, GLOBIOM and other sources.
-[[File:36405536.png|none|600px|thumb|<caption>Biomass resource use in POLES</caption>]]
-== Uranium resources==
-Uranium resources used in LWRs are represented at World level only (sources: IAEA / NEA Red Book, CEA estimates, ..). An Uranium price is derived from a global supply cost curve. LWR capacity development is also constrained by the amount of remaining resources. Fast breeders development is contrained by the production of waste from LWR.
-Sources of information include: IAEA/NEA Red Book, estimates from CNRS LPSC, ..
-== Hydro resources ==
-Hydro resources are defined for all 57 POLES countries / regions. They constraint the development of hydro power (which depends on identified projects and average power production costs).
-Sources of information include: WEC, IEA.
-== Solar resources ==
-Solar resources are defined as the maximum amount of solar energy that can harvested for the energy system. Solar energy in urban areas depends on the rooftop surface, solar energy in non-urban areas depends on land-use and distance to consuming centres. The resource is then used in the energy system depending on the economic conditions, considering netwrok constraints. The model uses mostly inside calculation considering solar irradiation, land use, population density and urban areas. In the case of the EU it can use information from the model GREEN-X.
-== Wind resources ==
-The model distinguishes between total resource and technical potential that is considered as harvestable, depending on distance to consuming centres and depths (for offshore resource). Total resources come from NREL estimates, technical potential can be internally calculated or also derived from NREL estimates. This potential is then used in the energy system depending on the economic conditions, considering network constraints. In the case of the EU the model can use information from the model GREEN-X.

Energy resource endowments - POLES: Difference between revisions

Latest revision as of 16:34, 22 December 2016

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